Method of managing the proactive spraying of environment ally-clean anti-fire chemical liquid on GPS-specified property surfaces so as to inhibit fire ignition and flame spread in the presence of wild fire

ABSTRACT

A method of managing the proactive spraying of environmentally-clean anti-fire (AF) chemical liquid on GPS-specified property surfaces so as to inhibit fire ignition and flame spread in the presence of wild fire. The method includes deploying a wireless system network supporting a command center, a network database, a plurality of mobile anti-fire chemical liquid spraying systems, and a plurality of mobile computing systems, each being operably connected to a wireless communication network. The GPS address of one or more GPS-specified parcels of property in a specified region, are registered in the network database. at least one of the mobile anti-fire chemical liquid spraying systems are deployed to a GPS-specified location, for spraying the GPS-specified parcels of property with an environmentally-clean anti-fire chemical liquid. A supply of said environmentally-clean anti-fire chemical liquid is deployed to the GPS-specified location of each mobile anti-fire chemical liquid spraying system, and the mobile anti-fire chemical liquid spraying system is filled with the supply of environmentally-clean anti-fire chemical liquid. The deployed anti-fire chemical liquid spraying system is used to apply the environmentally-clean anti-fire chemical liquid spray to the parcel of property, while remotely monitoring the application of the environmentally-clean anti-fire chemical liquid sprayed on the GPS-specified parcel of property on a given date, and automatically recording the GPS-tracked spraying operations in the network database. The data records are updated in the network database associated with each application of environmentally-clean anti-fire chemical liquid spray on one or more the GPS-specified parcels of property.

RELATED CASES

The present patent application is a Continuation of application Ser. No. 16/805,811 filed Mar. 1, 2020, which is a Continuation of U.S. patent application Ser. No. 15/866,451 filed Jan. 9, 2018, now U.S. Pat. No. 10,653,904, which is a Continuation-in-Part (CIP) of application Ser. No. 15/829,914 filed Dec. 2, 2017, now U.S. Pat. No. 10,260,232, incorporated herein by reference as if fully set forth herein.

BACKGROUND OF INVENTION Field of Invention

The present invention is directed towards improvements in science and technology applied in the defense of private and public property, and human and animal life, against the ravaging and destructive forces of wild fires caused by lightning, accident, arson and terrorism.

Brief Description of the State of Knowledge in the Art

The US federal government spent more than 3 billion US dollars on wild fire defense this year only to lose record numbers of acreage and homes. These figures relate solely to the US Forest Service costs and do not include figures from federal, state or local firefighting agencies. Over 8 million acres were scorched in 2017, a 50% increase in what is normally burned. Some estimates of the property damage in Northern California fires alone is $3 billion. The fires also killed more than 40 people and destroyed 8000 structures. Governor Brown of California is now asking President Trump for $7.5 billion dollars to rebuild Santa Rosa. However, the real problem is that the conventional fire suppression methods are not working as needed to protect neighborhoods, homes, business and human life from the raging forces of wild fire. More money is being spent and more people are being deployed, but the benefits are not being realized. There is a great need for better methods and apparatus for suppressing wild fires

FIG. 1 provides a table listing the primary conventional methods used for fighting and defending against wild fires and forest fires, alike: aerial water dropping illustrated in FIG. 2A; aerial fire retardant chemical (e.g. Phos-Chek® Fire Retardant) dropping illustrated in FIGS. 2B1, 2B2 and 2B3; physical fire break by bulldozing, to stall the advance of wild fire; physical fire break by pre-burning, to stall the advance of wild fire; and chemical fire break by dropping fire retardant chemical such as Phos-Chek® chemical over land, to stall the advance of wild fire. While these methods are used, the results have not been adequate in most instances where wild fires are raging across land under strong winds.

Recently, the State of California deployed its CAL FIRE™ mobile application for smartphones and other mobile computing devices, to provide users with notifications on where wild fires are burning at a given moment in time, the risks of wild fire in certain regions, ways of preparing for wild fires, and other useful information to help people stay out of harm's way during a wild fire. However, this notification system in its current state does little to help home and business owners to proactively defend their homes and business against raging forces of wild fires in any meaningful way.

Clearly, there is a great need and growing demand for new and improved methods of and apparatus for providing improved defense and protection against wild fires, while overcoming the shortcomings and drawbacks of prior art methods and apparatus.

OBJECTS AND SUMMARY OF THE PRESENT INVENTION

Accordingly, a primary object of the present is to provide new and improved method of and system and network for managing the supply, delivery and spray-application of environmentally-clean anti-fire (AF) liquid material on private and public properties to reduce the risks of damage and/or destruction to property and life caused by wild fires, while overcoming the shortcomings and drawbacks of prior art methods and apparatus.

Another object of the present is to provide method of reducing the risks of damage to private property due to wild fires by centrally managed application of AF chemical liquid spray to ground cover and building surfaces prior to arrival of the wild fires.

Another object of the present is to provide method of reducing the risks of damage to private property due to wild fires using a global positioning satellite (GPS) system and mobile communication messaging techniques, to help direct the application of AF chemical liquid prior to the arrival of wild wires.

Another object of the present invention is to provide a new and improved system for wild fire suppression and neighborhood and home defense comprising a platoon of small planes, all-terrain vehicles (ATVs) and other mobile systems adapted for spraying an environmentally-clean anti-fire (AF) chemical liquid that clings to the ground cover, and buildings, where applied in regions of high wild fire risk, that operates in both wet and dry states of application.

Another object of the present invention is to provide a new and improved system for wild fire suppression and home defense system comprising (i) a plurality of home wild-fire defense systems assigned to each home or building in the strategic area, for spraying the outside of their homes and surrounding ground cover with the environmentally-clean anti-fire (AF) spray liquid, (ii) a command center for managing wild fire pre-defense operations in the region, involving the application of the environmentally-clean anti-fire (AF) spray liquid to create and maintain strategic fire breaks in the region in advance of the outbreak of wild fires, and protection of homes and property in the region against wild fires breaking out in the region, and sending messages and instructions to home owners in the region as well as operators of the small planes and ATVs deployed in the system, and (iii) a mobile application installed on the mobile phone of each home owner in the strategic region, and configured for receiving email and/or SMS messages from a command center managing the system, and instructing home owners to pre-defend their homes using the environmentally-clean anti-fire spray liquid.

Another object of the present invention is to provide a new and improved system for wild fire suppression and home defense system, wherein each home defense spray system includes a GPS-tracking and radio-controlled circuit board to remotely monitor the location of each location-deployed home defense spray system and automatically monitor the anti-fire chemical liquid level in its storage tank, and automatically generate electronic refill orders sent to the command center, so that a third-party service can automatically replenish the tanks of such home-based systems with anti-fire liquid when the fluid level falls below a certain level in the GPS-tracked tank.

Another object of the present invention is to provide a new and improved system for wild fire suppression and home defense system, wherein the mobile application supporting the following functions: (i) sends automatic notifications from the command center to home owners with the mobile application, instructing them to spray their property and home at certain times with anti-fire chemical liquid in their tanks; (ii) the system will automatically monitor consumption of sprayed AF chemical liquid and generate auto-replenish order via its onboard GSM-circuits so as to achieve compliance with the home spray-based wild-fire-defense program, and report anti-fire liquid levels in each home-owner tank; and (iii) show status of wild fire risk in the region, and actions to the taken before wild fire outbreak.

Another object of the present invention is to provide a GPS-guided method of suppressing a wild fire raging towards a target region of land in a direction determined by currently blowing winds and other environmental and weather factors.

Another object of the present invention is to provide a method of reducing the risks of damage to public property due to wild fires by managed application of AF chemical liquid spray to ground cover and building surfaces prior to arrival of the wild fires.

Another object of the present invention is to provide a wireless system for managing the supply, delivery and spray-application of environmentally-clean anti-fire (AF) liquid on private and public property to reduce the risks of damage and/or destruction caused by wild fires.

Another object of the present invention is to provide a new and improved system for spraying a defensive path around vulnerable neighborhoods out in front of wild fires to make sure that an environmentally-safe fire break, created by the spray application of anti-fire (AF) liquid, defends homes from the destructive forces of raging wild fires.

Another object of the present invention is to provide a new and improved system and method of mitigating the damaging effects of wild fires by spraying environmentally-clean anti-fire (AF) chemical liquid in advance of wild fires, that do not depend on water to extinguish fire, such that, even after a month or two after spray application on dry brush around the neighborhood, the anti-fire chemical continues to work by stalling the ability of a fire to advance and consume homes.

Another object of the present invention is to provide new and improved methods of and apparatus for protecting wood-framed buildings from wild fires by automatically spraying water-based environmentally clean anti-fire chemical liquid over the exterior surfaces of the building, surrounding ground surfaces, shrubs, decking and the like, prior to wild fires reaching such buildings.

Another object of the present invention is to provide new and improved method of suppressing a wild fire raging across a region of land in the direction of the prevailing winds, by forming a multi-stage anti-fire (AF) chemical fire-break system comprising the step of (a) applying, prior to the wild fire reaching the specified target region of land, a low-density anti-fire (AF) liquid mist in advance of the wild fire so as to form a fire stall region, while providing a non-treated region of sufficient size between the front of the wild fire approaching the target region of land and the fire stall region, and (b) also applying a high-density anti-fire (AF) liquid spray in advance of the wild fire to form a fire break region beyond and contiguous with said fire stall region, wherein the fire stall region is formed before the wild fire reaches the fire stall region, and operates to reduce the free-radical chemical reactions raging in the wild fire so as to reduce the destructive energy of the wild fire by the time the wild fire reaches the fire break region, and enabling the fire break region to operate and significantly break the free radical chemical reactions in the wild fire when the wild fire reaches the fire break region, and thereby suppress the wild fire and protect the target region of land.

Another object of the present invention is to provide a new and improved method of and system network qualifying real property for reduced property insurance based on verified spray-based clean anti-fire (AF) chemical liquid treatment prior to presence of wild fires.

These and other benefits and advantages to be gained by using the features of the present invention will become more apparent hereinafter and in the appended Claims to Invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The following Objects of the Present Invention will become more fully understood when read in conjunction of the Detailed Description of the Illustrative Embodiments, and the appended Drawings, wherein:

FIG. 1 is a table listing conventional prior art methods for fighting and defending against wild fires including (i) aerial water drop methods using airplanes and helicopters, (ii) aerial fire retardant chemical (e.g. Phos-Chek® Fire Retardant) drop using airplanes and helicopters, (iii) physical fire breaks formed by bulldozing land and other landscaping methods to remove combustible vegetation from the land, (iv) physical fire breaks by pre-burning combustible material on the land, and (v) chemical fire break by fire retardant chemical drop;

FIG. 2A is a first image illustrating a prior art method of wild fire suppression involving an airplane dropping water on a wild fire from the sky;

FIG. 2B1 is a second image illustrating a prior art method of wild fire suppression involving an airplane dropping chemical fire retardant (e.g. Phos-Chek®) on a wild fire from the sky;

FIG. 2B2 is third image showing a prior art ground-based tank containing the chemical fire retardant (e.g. Phos-Chek®) fire retardant chemical) that is shown being contained in a storage tank in FIG. 2B2, and dropped from an airplane in FIG. 2B1;

FIG. 2B3 is a fourth image showing a prior art ground-based tank containing a supply of Phos-Chek® fire retardant chemical mixed in the tank shown in FIG. 2B3, and dropped from an airplane in FIG. 2B1;

FIGS. 3A, 3B, 3C, 3D and 3E show some exemplary graphical user interfaces (GUI) screens supported by the prior art CAL FIRE™ mobile application running on an Apple iPhone™ device, or other mobile computing device, designed to help members of the public to prepare for wild fires;

FIG. 4 is schematic representation of the wireless system network of the present invention designed for managing the supply, delivery and spray-application of environmentally-clean anti-fire (AF) liquid on private and public property to reduce the risks of property damage and/or destruction and harm to life caused by wild fires, and shown comprising GPS-tracked anti-fire (AF) liquid spray ground vehicles, GPS-tracked anti-fire liquid spray air vehicles, GPS-tracked anti-fire liquid spray backpack systems for spraying houses and surrounding properties, GPS-tracked anti-fire liquid spraying systems for spraying private real property and buildings, GPS-tracked liquid spraying systems for spraying public real property and buildings, mobile computing systems running the mobile application of the present invention and used by property owners, residents, fire departments, insurance underwriters, government officials, medical personal and others, remote data sensing and capturing systems for remotely monitoring land and wild fires wherever they may break out, a GPS system for providing GPS-location services to each and every system components in the system network, and one or more data center containing clusters of web, application and database servers for supporting wire wild alert and notification systems, and microservices configured for monitoring and managing the system and network of GPS-tracking anti-fire liquid spraying systems and mobile computing and communication devices configured in accordance with the principles of the present invention;

FIG. 4A is a schematic representation illustrating exemplary multispectral imaging (MSI) and hyperspectral imaging (HSI) based remote sensing technology platforms supported by the US Geological Survey (USGS) Agency including, for example, the MODIS (Moderate Resolution Imaging Spectroradiometer) satellite system, the World View 2 Satellite System, the Octocopter unmanned airborne system (UAS) (e.g. OnyxStar Hyra-12 heavy lifting drone), and the SenseFly eBee SQ UAS, for use in supporting and practicing the system network of the present invention;

FIG. 4B is a perspective view of the OnyxStar Hyra-12 heavy lifter drone supporting MSI and HSI camera systems, and providing remove data sensing services that can be used to help carry out the GPS-directed methods of wild fire suppression disclosed herein in accordance with the principles of the present invention;

FIG. 5A is a perspective view of an exemplary mobile computing device deployed on the system network of the present invention, supporting (i) the mobile anti-fire spray management application of the present invention deployed as a component of the system network of the present invention as shown in FIGS. 12 through 13D, as well as (ii) conventional wildfire alert and notification systems as shown in FIGS. 3A through 3E;

FIG. 5B shows a system diagram for an exemplary mobile client computer system deployed on the system network of the present invention;

FIG. 6A is a perspective view of a mobile GPS-tracked anti-fire (AF) liquid spraying system supported on a set of wheels, with integrated supply tank and rechargeable-battery operated electric spray pump, for deployment at private and public properties having building structures, for spraying the same with environmentally-clean anti-fire (AF) liquid in accordance with the principles of the present invention;

FIG. 6B is a schematic representation of the GPS-tracked mobile anti-fire (AF) chemical liquid spraying system shown in FIG. 6A, comprising a GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem interfaced with a micro-computing platform for monitoring the spraying of AF chemical liquid from the system when located at specific GPS-indexed location coordinates, and automatically logging and recording such AF spray application operations within the network database system;

FIG. 7A is a perspective view of a GPS-tracked manned or autonomous vehicle system for spraying AF chemical liquid on building and ground surfaces for spraying the same with environmentally-clean anti-fire (AF) chemical liquid in accordance with the principles of the present invention;

FIG. 7B is a schematic representation of the manned or autonomously-driven vehicle system shown in FIG. 7A, comprising a GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem interfaced with a micro-computing platform for monitoring the spraying of AF chemical liquid from the vehicle when located at any specific GPS-indexed location coordinates, and automatically logging and recording such AF spray application operations within the network database system;

FIG. 8A is a perspective view of an autonomously-driven or remotely-controlled unmanned airborne system (i.e. UAS or “drone”) adapted for spraying AF chemical liquid on building and ground surfaces for spraying the same with environmentally-clean anti-fire (AF) liquid in accordance with the principles of the present invention;

FIG. 8B is a schematic representation of the autonomously-driven or remotely-controlled aircraft system (i.e. drone) shown in FIG. 8A, comprising a GPS-tracked and remotely monitored AF chemical liquid spray control subsystem interfaced with a micro-computing platform for monitoring the spraying of AF chemical liquid from the aircraft when located at specific GPS-indexed location coordinates, and automatically logging and recording such AF spray application operations within the network database system;

FIG. 9A is a perspective view of a GPS-tracked aircraft system (i.e. helicopter) adapted for spraying an environmentally-clean anti-fire (AF) liquid AF chemical liquid, from the air, onto ground surfaces in accordance with the principles of the present invention;

FIG. 9B is a schematic representation of the GPS-tracked aircraft system (i.e. helicopter) shown in FIG. 9A, comprising a GPS-tracked and remotely monitored AF chemical liquid spray control subsystem interfaced with a micro-computing platform for monitoring the spraying of AF chemical liquid from the aircraft when located at specific GPS-indexed location coordinates, and automatically logging and recording such AF spray application operations within the network database system;

FIG. 10A is a GPS-tracked all-terrain vehicle (ATV) system adapted for spraying ground surfaces with anti-fire (AF) liquid in accordance with the principles of the present invention;

FIG. 10B is the GPS-tracked all-terrain vehicle (ATV) system shown in FIG. 10A, comprising a GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem interfaced with a micro-computing platform for monitoring the spraying of AF chemical liquid from the ATV system when located at specific GPS-indexed location coordinates, and automatically logging and recording such AF spray application operations within the network database system;

FIG. 11 is a schematic representation of a schema for the network database (RDBMS) supported by the system network of the present invention, showing the primary enterprise level objects supported in the database tables created in the network database using the schema, and the relationships that are specified or indicated;

FIG. 12 is an exemplary wire-frame model of a graphical user interface supported by mobile application configured for use by a first specific class of registered users (e.g. property parcel owners, contractors and/or agents, residents, government officials, and others) to request and receive services, including notices and orders, supported by the system network of the present invention;

FIG. 12A is an exemplary wire-frame model of a graphical user interface supported by the mobile application showing a user updating the registration profile as a task on the system network;

FIG. 12B is an exemplary wire-frame model of a graphical user interface supported by the mobile application showing a user receiving a message request (via email, SMS messaging and/or push-notifications) issued from the command center to spray GPS-specified private property parcel(s) with clean anti-fire (AF) chemical liquid and registered equipment;

FIG. 12C is an exemplary wire-frame model of a graphical user interface supported by the mobile application showing a user receiving a request/notice of order (via email, SMS messaging and/or push-notifications) to wild-fire spray-protect GPS-specified public property parcel(s) with clean anti-fire (AF) liquid to create and maintain a GPS-specified public firebreak, maintained on public property;

FIG. 12D is an exemplary wire-frame model of a graphical user interface supported by the mobile application showing a user requesting a refill supply of clean anti-fire (AF) chemical liquid for supply to GPS-specified spray equipment registered on the system network;

FIG. 13 is an exemplary wire-frame model of a graphical user interface supported by the mobile application configured for second specific class of registered users, namely, command center administrators, enabling such users to issue wild-fire protection orders, plan wild-fire protection tasks, generate wild-fire and protection reports, and send and receive messages to users on the system network;

FIG. 13A is an exemplary wire-frame model of a graphical user interface supported by the mobile application for use by command center administrators to issue wild-fire protection orders using the system network of the present invention;

FIG. 13B exemplary wire-frame model of a graphical user interface supported by the mobile application for use by command center administrators to issue wild-fire protection orders involving the creation and maintenance of a clean AF-based chemical firebreak using the methods of the present invention, as illustrated in FIGS. 18 through 25B;

FIG. 13C is an exemplary wire-frame models of a graphical user interface supported by the mobile application for use by command center administrators to order the creation and/or maintenance of a GPS-specified clean AF-based chemical firebreak on one or more public/private property parcels, using the methods of the present invention;

FIG. 13D is an exemplary wire-frame models of a graphical user interface for the mobile application used by command center administrators to receive messages from users including property owners and contractors requesting refills for clean anti-fire (AF) chemical liquid for GPS-specified spray system equipment;

FIG. 14 is a graphical representation of an exemplary fire hazard severity zone (FHSZ) map generated by the CAF FIRE™ System in state responsibility areas of the State of California, and accessible through the mobile application, for use while informing the strategic application of environmentally-clean anti-fire (AF) liquid spray onto specified regions of property prior to the arrival of wild fires, using the system network of the present invention;

FIG. 15 is an exemplary anti-fire (AF) spray protection map generated by the system network of the present invention, showing houses and buildings that have been sprayed, and not-sprayed, with state/county-issued clean anti-fire (AF) liquid as of the report date 15 Dec. 2017;

FIG. 16 is an exemplary anti-fire spray protection task report generated by the system of the present invention for state/county xxx on 15 Dec. 2017, indicating which properties on what streets, in what town, county, state, requires the reapplication of AF chemical liquid spray treatment in view of factors such as weather (e.g. rainfall, sunlight) and passage of time since last AF chemical liquid spray application;

FIG. 17 is a schematic representation showing a plan view of a wild fire emerging from a forest region and approaching a neighboring town moving in the direction of prevailing winds;

FIG. 18 is a graphical representation illustrating a method of suppressing a wild fire raging across a region of land in the direction of the prevailing winds, by forming a multi-stage anti-fire (AF) chemical fire-break system, by GPS-controlled application of anti-fire (AF) liquid mist and spray streams, wherein the method comprises the step of (a) applying, prior to the wild fire reaching the specified target region of land, a low-density anti-fire (AF) liquid mist in advance of the wild fire so as to form a fire stall region, while providing a non-treated region of sufficient size between the front of the wild fire approaching the target region of land and the fire stall region, and (b) also applying a high-density anti-fire (AF) liquid spray in advance of the wild fire to form a fire break region beyond and contiguous with said fire stall region, wherein the fire stall region is formed before said wild fire reaches the fire stall region, and operates to reduce the free-radical chemical reactions raging in the wild fire so as to reduce the destructive energy of the wild fire by the time the wild fire reaches the fire break region, and enabling the fire break region to operate and significantly break the free radical chemical reactions in the wild fire when the wild fire reaches the fire break region, and thereby suppress the wild fire and protect the target region of land;

FIGS. 19A and 19B set forth a flow chart describing the high level steps of the method of suppressing a wild fire raging towards a target region of land in a direction determined by prevailing winds and other environmental and weather factors, as schematically illustrated in FIG. 18 ;

FIG. 20 is a graphical representation illustrating a method of reducing the risks of damage to private property due to wild fires by GPS-controlled application of anti-fire (AF) liquid spray, using the system network of the present invention;

FIGS. 21A, 21B and 21C, taken together, set forth a flow chart describing the high level steps carried out by the method of reducing the risks of damage to private property due to wild fires by managed application of anti-fire (AF) liquid spray, using the system network and methods of the present invention;

FIG. 22 is a graphical illustration showing a method of reducing the risks of damage to public property due to wild fires, by GPS-controlled application of anti-fire (AF) chemical liquid spray over ground cover and building surfaces prior to the arrival of wild fires, using the system network and methods of the present invention;

FIGS. 23A, 23B and 23C, taken together, set forth a flow chart describing the high level steps carried out by the method of reducing the risks of damage to public property due to wild fires by GPS-controlled application of anti-fire (AF) liquid spray, using the system network and methods of the present invention;

FIG. 24 is a graphical illustration showing a method of remotely managing the GPS-controlled application of anti-fire (AF) liquid spray to ground cover and buildings so as to reduce the risks of damage due to wild fires, using the system network and methods of the present invention;

FIGS. 25A and 25B, taken together, set forth a flow chart describing the high level steps carried out by the method of GPS-controlled application of anti-fire (AF) liquid spray to ground cover and buildings so as to reduce the risks of damage due to wild fires, using the system network and methods of the present invention; and

FIG. 26 is a flow chart describing the primary steps of the method of qualifying real property for reduced property insurance, based on verified spray-based clean anti-fire (AF) chemical liquid treatment prior to presence of wild fires, using the system network and methods of the present invention.

DETAILED DESCRIPTION OF THE ILLUSTRATIVE EMBODIMENTS OF THE PRESENT INVENTION

Referring to the accompanying Drawings, like structures and elements shown throughout the figures thereof shall be indicated with like reference numerals.

Wireless System Network for Managing the Supply, Delivery and Spray-Application of Environmentally-Clean Anti-Fire (AF) Liquid on Private and Public Property to Reduce the Risks of Damage and/or Destruction Caused by Wild Fires

FIG. 4 shows the wireless system network of the present invention 1 designed for managing the supply, delivery and spray-application of environmentally-clean anti-fire (AF) liquid on private and public property to reduce the risks of damage and/or destruction caused by wild fires. As shown, the wireless system network 1 comprises a distribution of system components, namely: GPS-tracked anti-fire (AF) liquid spray ground vehicles 2 (e.g. all-terrain vehicles or ATVs) as shown in FIGS. 7A and 7B, and 10A and 10B, for applying AF chemical liquid spray (e.g. Hartindo AF31 fire inhibitor chemical from Hartindo Chemical, Indonesia) from the ground to ground surfaces, brush, and other forms of organic material; GPS-tracked anti-fire liquid spray air-based vehicles 3 as shown in FIGS. 9A, 9B, and 8A, 8B for applying AF chemical liquid spray (e.g. Hartindo AF31 fire inhibitor chemical liquid) from the air to ground surfaces, brush, bushes and other forms of organic material; GPS-tracked mobile anti-fire liquid spraying systems 4 (e.g. including wheel supported, and backpack-carried systems) as shown in FIGS. 6A and 6B for applying AF chemical liquid spray (e.g. Hartindo AF31 fire inhibitor chemical liquid) to ground surfaces, brush, bushes, decks, houses, buildings, and other forms of organic material and property surrounding houses; GPS-tracked/GSM-linked anti-fire liquid spraying systems 5 as shown in FIGS. 10A, 10B, 8A, 8B, and 7A, 7B for applying AF chemical liquid spray (e.g. Hartindo AF31 fire inhibitor chemical liquid) to private real property, buildings and surrounding areas; GPS-tracked/GSM-linked liquid spraying systems 6 as shown in FIGS. 10A, 10B, 8A, 8B, and 7A, 7B for applying AF chemical liquid spray (e.g. Hartindo AF31 fire inhibitor chemical liquid) to public real property and buildings and surrounding properties; a GPS-indexed real-property (land) database system 7 for storing the GPS coordinates of the vertices and maps of all land parcels, including private property and building 17 and public property and building 18, situated in every town, county and state in the region over which the system network 1 is used to manage wild fires as they may occur; a cellular phone, GSM, and SMS messaging systems and email servers, collectively 16; and one or more data centers 8 for monitoring and managing GPS-tracking/GSM-linked anti-fire (AF) liquid supply and spray systems, including web servers 9A, application servers 9B and database servers 9C (e.g. RDBMS) operably connected to the TCP/IP infrastructure of the Internet 10, and including a network database 9C1, for monitoring and managing the system and network of GPS-tracking anti-fire liquid spraying systems and various functions supported by the command center 19, including the management of wild fire suppression and the GPS-guided application of anti-fire (AF) chemical liquid over public and private property, as will be described in greater technical detail hereinafter. As shown, each data center 8 also includes an SMS server 9D and an email message server 9E for communicating with registered users on the system network 1 who use a mobile computing device (e.g. an Apple® iPhone or iPad tablet) 11 with the mobile application 12 installed thereon and configured for the purposes described herein. Such communication services will include SMS/text, email and push-notification services known in the mobile communications arts.

As shown in FIG. 4 , the GPS-indexed real-property (land) database system 7 will store the GPS coordinates of the vertices and maps of all land parcels contained in every town, county and state of the region over which the system network is deployed and used to manage wild fires as they may occur. Typically, databases and data processing methods, equipment and services known in the GPS mapping art, will be used to construct and maintain such GPS-indexed databases 7 for use by the system network of the present invention, when managing GPS-controlled application of clean anti-fire (AF) chemical liquid spray and mist over GPS-specified parcels of land, at any given time and date, under the management of the system network of the present invention. Examples of such GPS-indexed maps of land parcels are reflected by the task report shown in FIG. 16 , and examples of GPS-indexed maps are shown in the schematic illustrations depicted in FIGS. 18, 20, 22 and 24 .

As shown in FIG. 4 , the system network 1 also includes a GPS system 100 for transmitting GPS reference signals transmitted from a constellation of GPS satellites deployed in orbit around the Earth, to GPS transceivers installed aboard each GPS-tracking ground-based or air-based anti-fire (AF) liquid misting/spraying system of the present invention, shown in FIGS. 6A through 10B, as part of the illustrative embodiments. From the GPS signals it receives, each GPS transceiver aboard such AF liquid spraying/misting systems is capable of computing in real-time the GPS location of its host system, in terms of longitude and latitude. In the case of the Empire State Building in NYC, N.Y., its GPS location is specified as: N40° 44.9064′, W073° 59.0735′; and in number only format, as: 40.748440, −73.984559, with the first number indicating latitude, and the second number representing longitude (the minus sign indicates “west”).

As shown in FIG. 4 , the system network 1 further includes multi-spectral imaging (MSI) systems and/or hyper-spectral-imaging (HSI) systems 14 for remotely data sensing and gathering data about wild fires and their progress. Such MSI and HSI systems may be space/satellite-based and/or drone-based (supported on an unmanned airborne vehicle or UAV). Drone-based systems can be remotely-controlled by a human operator, or guided under an artificial intelligence (AI) navigation system. Such AI-based navigation systems may be deployed anywhere, provided access is given to such remote navigation system the system network and its various systems. Typically, the flight time will be limited to under 1 hour using currently available battery technology, so there will be a need to provide provisions for recharging the batteries of such drones/UASs in the field, necessitating the presence of human field personnel to support the flight and remote data sensing and mapping missions of each such deployed drone, flying about raging wild fires, in connection with the system network of the present invention.

During each wild fire data sensing and mapping mission, carried out by such UAS, a series of MSI images and HSI images can be captured during a wild fire, and mapped to GPS-specific coordinates, and this mapped data can be transmitted back to the system network for storage, analysis and generation of GPS-specified flight plans for anti-fire (AF) chemical liquid spray and misting operations carried out using the methods illustrated in FIGS. 17, 18, 19A and 19B seeking to stall and suppress such wild fires, and mitigate risk of damage to property and harm to human and animal life.

FIG. 4A shows a suite of MSI and HSI remote sensing and mapping instruments and technology 14 that is currently being used by the US Geological Survey (USGS) Agency to collect, monitor, analyze, and provide science about natural resource conditions, issues, and problems on Earth. It is an object of the present invention to exploit such instruments and technology when carrying out and practicing the various methods of the present invention disclosed herein. As shown in FIG. 4A, these MSI/HSI remote sensing technologies 14 include: MODIS (Moderate Resolution Imaging Spectro-radiometer) satellite system 14A for generating MODIS imagery subsets from MODIS direct readout data acquired by the USDA Forest Service Remote Sensing Applications Center, to produce satellite fire detection data maps and the like https://fsapps.nwcg.gov/afm/activefiremaps.php; the World View 2 Satellite System 14B manufacture from the Ball Aerospace & Technologies and operated by DigitalGlobe, for providing commercially available panchromatic (B/W) imagery of 0.46 meter resolution, and eight-band multi-spectral imagery with 1.84 meter resolution; Octocopter UAS (e.g. OnyxStar Hyra-12 heavy lifting drone) 14C as shown in FIG. 4B supporting MSI and HSI camera systems for spectral imaging applications, http://www.onyxstar.net and http://www.genidrone.com; and SenseFly eBee SQ UAS 14D for capturing and mapping high-resolution aerial multi-spectral images https://www.sensefly.com/drones/ebee-sq.html.

Any one or more of these types of remote data sensing and capture instruments, tools and technologies can be integrated into and used by the system network 1 for the purpose of (i) determining GPS-specified flight/navigation plans for GPS-tracked anti-fire (AF) chemical liquid spraying and misting aircraft and ground-based vehicle systems, respectively, shown in FIGS. 9A, 9B, 8A, 8B, 10A, 10B, and 7A, 7B, and (ii) practicing the various GPS-guided methods of wild fire suppression illustrated in FIGS. 17 through 25B, and described in detail herein.

Specification of the Network Architecture of the System Network of the Present Invention

FIG. 4 illustrates the network architecture of the system network 1 implemented as a stand-alone platform deployed on the Internet. As shown, the Internet-based system network comprises: cellular phone and SMS messaging systems and email servers 16 operably connected to the TCP/IP infrastructure of the Internet 10; a network of mobile computing systems 11 running enterprise-level mobile application software 12, operably connected to the TCP/IP infrastructure of the Internet 10; an array of mobile GPS-tracked anti-fire (AF) liquid spraying systems (20, 30, 40, 50), each provided with GPS-tracking and having wireless internet connectivity with the TCP/IP infrastructure of the Internet 10, using various communication technologies (e.g. GSM, BlueTooth, WIFI, and other wireless networking protocols well known in the wireless communications arts); and one or more industrial-strength data center(s) 8, preferably mirrored with each other and running Border Gateway Protocol (BGP) between its router gateways, and operably connected to the TCP/IP infrastructure of the Internet 10.

As shown in FIG. 4 , each data center 8 comprises: the cluster of communication servers 9A for supporting http and other TCP/IP based communication protocols on the Internet (and hosting Web sites); a cluster of application servers 9B; the cluster of RDBMS servers 9C configured within a distributed file storage and retrieval ecosystem/system, and interfaced around the TCP/IP infrastructure of the Internet well known in the art; the SMS gateway server 9D supporting integrated email and SMS messaging, handling and processing services that enable flexible messaging across the system network, supporting push notifications; and the cluster of email processing servers 9E.

Referring to FIG. 4 , the cluster of communication servers 9A is accessed by web-enabled mobile computing clients 11 (e.g. smart phones, wireless tablet computers, desktop computers, computer workstations, etc.) used by many stakeholders accessing services supported by the system network 1. The cluster of application servers 9A implement many core and compositional object-oriented software modules supporting the system network 1. Typically, the cluster of RDBMS servers 9C use SQL to query and manage datasets residing in its distributed data storage environment, although non-relational data storage methods and technologies such as Apache's Hadoop non-relational distributed data storage system may be used as well.

As shown in FIG. 4 , the system network architecture shows many different kinds of users supported by mobile computing devices 11 running the mobile application 12 of the present invention, namely: the plurality of mobile computing devices 11 running the mobile application 12, used by fire departments and firemen to access services supported by the system network 1; the plurality of mobile computing systems 11 running mobile application 12, used by insurance underwriters and agents to access services on the system network 1; the plurality of mobile computing systems 11 running mobile application 12, used by building architects and their firms to access the services supported by the system network 1; the plurality of mobile client systems 11 (e.g. mobile computers such as iPad, and other Internet-enabled computing devices with graphics display capabilities, etc.) used by spray-project technicians and administrators, and running a native mobile application 12 supported by server-side modules, and the various illustrative GUIs shown in FIGS. 12 through 13D, supporting client-side and server-side processes on the system network of the present invention; and a GPS-tracked anti-fire (AF) liquid spraying systems 20, 30, 40 and 50 for spraying buildings and ground cover to provide protection and defense against wild-fires.

In general, the system network 1 will be realized as an industrial-strength, carrier-class Internet-based network of object-oriented system design, deployed over a global data packet-switched communication network comprising numerous computing systems and networking components, as shown. As such, the information network of the present invention is often referred to herein as the “system” or “system network”. The Internet-based system network can be implemented using any object-oriented integrated development environment (IDE) such as for example: the Java Platform, Enterprise Edition, or Java EE (formerly J2EE); Websphere IDE by IBM; Weblogic IDE by BEA; a non-Java IDE such as Microsoft's .NET IDE; or other suitably configured development and deployment environment well known in the art. Preferably, although not necessary, the entire system of the present invention would be designed according to object-oriented systems engineering (OOSE) methods using UML-based modeling tools such as ROSE by Rational Software, Inc. using an industry-standard Rational Unified Process (RUP) or Enterprise Unified Process (EUP), both well known in the art. Implementation programming languages can include C, Objective C, C, Java, PHP, Python, Google's GO, and other computer programming languages known in the art. Preferably, the system network is deployed as a three-tier server architecture with a double-firewall, and appropriate network switching and routing technologies well known in the art. In some deployments, private/public/hybrid cloud service providers, such Amazon Web Services (AWS), may be used to deploy Kubernetes, an open-source software container/cluster management/orchestration system, for automating deployment, scaling, and management of containerized software applications, such as the mobile enterprise-level application 12 of the present invention, described above.

Specification of System Architecture of an Exemplary Mobile Smartphone System Deployed on the System Network of the Present Invention

FIG. 5A shows an exemplary mobile computing device 11 deployed on the system network of the present invention, supporting conventional wildfire alert and notification systems (e.g. CAL FIRE® wild fire notification system 14), as well as the mobile anti-fire spray management application 12 of the present invention, that is deployed as a component of the system network 1.

FIG. 5B shows the system architecture of an exemplary mobile client computing system 11 that is deployed on the system network 1 and supporting the many services offered by system network servers 9A, 9B, 9C, 9D, 9E. As shown, the mobile smartphone device 11 can include a memory interface 202, one or more data processors, image processors and/or central processing units 204, and a peripherals interface 206. The memory interface 202, the one or more processors 204 and/or the peripherals interface 206 can be separate components or can be integrated in one or more integrated circuits. The various components in the mobile device can be coupled by one or more communication buses or signal lines. Sensors, devices, and subsystems can be coupled to the peripherals interface 206 to facilitate multiple functionalities. For example, a motion sensor 210, a light sensor 212, and a proximity sensor 214 can be coupled to the peripherals interface 206 to facilitate the orientation, lighting, and proximity functions. Other sensors 216 can also be connected to the peripherals interface 206, such as a positioning system (e.g. GPS receiver), a temperature sensor, a biometric sensor, a gyroscope, or other sensing device, to facilitate related functionalities. A camera subsystem 220 and an optical sensor 222, e.g. a charged coupled device (CCD) or a complementary metal-oxide semiconductor (CMOS) optical sensor, can be utilized to facilitate camera functions, such as recording photographs and video clips. Communication functions can be facilitated through one or more wireless communication subsystems 224, which can include radio frequency receivers and transmitters and/or optical (e.g. infrared) receivers and transmitters. The specific design and implementation of the communication subsystem 224 can depend on the communication network(s) over which the mobile device is intended to operate. For example, the mobile device 11 may include communication subsystems 224 designed to operate over a GSM network, a GPRS network, an EDGE network, a Wi-Fi or WiMax network, and a Bluetooth™ network. In particular, the wireless communication subsystems 224 may include hosting protocols such that the device 11 may be configured as a base station for other wireless devices. An audio subsystem 226 can be coupled to a speaker 228 and a microphone 230 to facilitate voice-enabled functions, such as voice recognition, voice replication, digital recording, and telephony functions. The I/O subsystem 240 can include a touch screen controller 242 and/or other input controller(s) 244. The touch-screen controller 242 can be coupled to a touch screen 246. The touch screen 246 and touch screen controller 242 can, for example, detect contact and movement or break thereof using any of a plurality of touch sensitivity technologies, including but not limited to capacitive, resistive, infrared, and surface acoustic wave technologies, as well as other proximity sensor arrays or other elements for determining one or more points of contact with the touch screen 246. The other input controller(s) 244 can be coupled to other input/control devices 248, such as one or more buttons, rocker switches, thumb-wheel, infrared port, USB port, and/or a pointer device such as a stylus. The one or more buttons (not shown) can include an up/down button for volume control of the speaker 228 and/or the microphone 230. Such buttons and controls can be implemented as a hardware objects, or touch-screen graphical interface objects, touched and controlled by the system user. Additional features of mobile smartphone device 11 can be found in U.S. Pat. No. 8,631,358 incorporated herein by reference in its entirety.

Different Ways of Implementing the Mobile Client Machines and Devices on the System Network of the Present Invention

In one illustrative embodiment, the enterprise-level system network is realized as a robust suite of hosted services delivered to Web-based client subsystems 1 using an application service provider (ASP) model. In this embodiment, the Web-enabled mobile application 12 can be realized using a web-browser application running on the operating system (OS) (e.g. Linux, Application IOS, etc.) of a mobile computing device 11 to support online modes of system operation, only. However, it is understood that some or all of the services provided by the system network 1 can be accessed using Java clients, or a native client application, running on the operating system of a client computing device, to support both online and limited off-line modes of system operation. In such embodiments, the native mobile application 12 would have access to local memory (e.g. a local RDBMS) on the client device 11, accessible during off-line modes of operation to enable consumers to use certain or many of the system functions supported by the system network during off-line/off-network modes of operation. It is also possible to store in the local RDBMS of the mobile computing device 11 most if not all relevant data collected by the mobile application for any particular fire-protection spray project, and to automatically synchronize the dataset for user's projects against the master datasets maintained in the system network database 9C1, within the data center 8 shown in FIG. 4 . This way, when using a native application, during off-line modes of operation, the user will be able to access and review relevant information regarding any building spray project, and make necessary decisions, even while off-line (i.e. not having access to the system network).

As shown and described herein, the system network 1 has been designed for several different kinds of user roles including, for example, but not limited to: (i) public and private property owners, residents, fire departments, local, county, state and federal officials; and (ii) wild fire suppression administrators, contractors, technicians et al registered on the system network. Depending on which role, for which the user requests registration, the system network will request different sets of registration information, including name of user, address, contact information, etc. In the case of a web-based responsive application on the mobile computing device 11, once a user has successfully registered with the system network, the system network will automatically serve a native client GUI, or an HTML5 GUI, adapted for the registered user. Thereafter, when the user logs into the system network, using his/her account name and password, the system network will automatically generate and serve GUI screens described below for the role that the user has been registered with the system network.

In the illustrative embodiment, the client-side of the system network 1 can be realized as mobile web-browser application, or as a native application, each having a “responsive-design” and adapted to run on any client computing device (e.g. iPhone, iPad, Android or other Web-enabled computing device) 11 and designed for use by anyone interested in managing, monitoring and working to defend against the threat of wild fires.

Specification of the Mobile GPS-Tracked Anti-Fire (AF) Liquid Spraying System of the Present Invention

FIG. 6A shows a mobile GPS-tracked anti-fire (AF) liquid spraying system 20 supported on a set of wheels 20A, having an integrated supply tank 20B and rechargeable-battery operated electric spray pump 20C, for deployment at private and public properties having building structures, for spraying the same with environmentally-clean anti-fire (AF) liquid using a spray nozzle assembly 20D connected to the spray pump 20C by way of a flexible 20E.

FIG. 6B shows the GPS-tracked mobile anti-fire liquid spraying system 20 of FIG. 6A as comprising a number of subcomponents, namely: a GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 20F; a micro-computing platform or subsystem 20G interfaced with the GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 20F by way of a system bus 20I; and a wireless communication subsystem 20H interfaced to the micro-computing platform 20G via the system bus 20I. As configured, the GPS-tracked mobile anti-fire liquid spraying system 20 enables and supports (i) the remote monitoring of the spraying of anti-fire (AF) chemical liquid from the system 20 when located at specific GPS-indexed location coordinates, and (ii) the logging of all such GPS-indexed spray application operations, and recording the data transactions thereof within a local database maintained within the micro-computing platform 20G, as well as in the remote network database 9C1 maintained at the data center 8 of the system network 1.

As shown in FIG. 6B, the micro-computing platform 20G comprises: data storage memory 20G1; flash memory (firmware storage) 20G2; a programmable microprocessor 20G3; a general purpose I/O (GPIO) interface 20G4; a GPS transceiver circuit/chip with matched antenna structure 20G5; and the system bus 20I which interfaces these components together and provides the necessary addressing, data and control signal pathways supported within the system 20.

As shown in FIG. 6B, the wireless communication subsystem 20H comprises: an RF-GSM modem transceiver 20H1; a T/X amplifier 20H2 interfaced with the RF-GSM modem transceiver 20H1; and a WIFI and Bluetooth wireless interfaces 20H3.

As shown in FIG. 6B, the GPS-tracked and remotely-controllable anti-fire (AF) chemical liquid spray control subsystem 20F comprises: anti-fire chemical liquid supply sensor(s) 20F1 installed in or on the anti-fire chemical liquid supply tank 20B to produce an electrical signal indicative of the volume or percentage of the AF liquid supply tank containing AF chemical liquid at any instant in time, and providing such signals to the AF liquid spraying system control interface 20F4; a power supply and controls 20F2 interfaced with the liquid pump spray subsystem 20C, and also the AF liquid spraying system control interface 20F4; manually-operated spray pump controls interface 20F3, interfaced with the AF liquid spraying system control interface 20F4; and the AF liquid spraying system control interface 20F4 interfaced with the micro-computing subsystem 20G, via the system bus 20I. The flash memory storage 20G2 contains microcode that represents a control program that runs on the microprocessor 20G3 and realizes the various GPS-specified AF chemical liquid spray control, monitoring, data logging and management functions supported by the system 20.

In the preferred embodiment, the environmentally-clean anti-fire (AF) chemical liquid is preferably Hartindo AF31 Total Fire Inhibitor, developed by Hartindo Chemicatama Industri of Jakarta, Indonesia, and commercially-available from Newstar Chemicals (M) SDN. BHD of Selangor Darul Ehsan, Malaysia, http://newstarchemicals.com/products.html. When so treated, combustible products will prevent flames from spreading, and confine fire to the ignition source which can be readily extinguished, or go out by itself. In the presence of a flame, the chemical molecules in both dry and wet coatings, formed with Hartindo AF31 liquid, interferes with the free radicals (H+, OH−, O) involved in the free-radical chemical reactions within the combustion phase of a fire, and breaks these free-radical chemical reactions and extinguishes the fire's flames.

Specification of GPS-Tracked Manned or Autonomous Vehicle for Spraying Anti-Fire (AF) Liquid on Building and Ground Surfaces

FIG. 7A shows a mobile GPS-tracked manned or autonomous vehicle anti-fire (AF) liquid spray vehicle system 30 for spraying environmentally-clean anti-fire (AF) chemical liquid on exterior building surfaces and ground surfaces in accordance with the principles of the present invention. As shown, the vehicle system 30 is supported on a set of wheels 30A driven by a propulsion drive subsystem 30 and navigated by GPS-guided navigation subsystem 301, and carrying an integrated supply tank 30B with either rechargeable-battery-operated electric-motor driven spray pump, or gasoline/diesel or propane operated motor-driven spray pump, 30C, for deployment on private and public property parcels having building structures, for spraying the same with environmentally-clean anti-fire (AF) liquid using a spray nozzle assembly 30D connected to the spray pump 30C by way of a flexible hose 30E.

FIG. 7B shows the GPS-tracked mobile anti-fire liquid spraying system 30 of FIG. 7A as comprising a number of subcomponents, namely: a GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 30F; a micro-computing platform or subsystem 30G interfaced with the GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 30F by way of a system bus 30I; a wireless communication subsystem 30H interfaced to the micro-computing platform 30G via the system bus 30I; and a vehicular propulsion and navigation subsystem 30I employing a propulsion subsystem 30I1 and AI-driven or manually-driven navigation subsystem 30I2.

As configured in the illustrative embodiment, the GPS-tracked mobile anti-fire liquid spraying system 30 enables and supports (i) the remote monitoring of the spraying of anti-fire (AF) chemical liquid from the system 30 when located at specific GPS-indexed location coordinates, and (ii) the logging of all such GPS-indexed spray application operations, and recording the data transactions thereof within a local database maintained within the micro-computing platform 30G, as well as in the remote network database 9C1 maintained at the data center 8 of the system network 1.

As shown in FIG. 7B, the micro-computing platform 30G comprises: data storage memory 30G1; flash memory (firmware storage) 30G2; a programmable microprocessor 30G3; a general purpose I/O (GPIO) interface 30G4; a GPS transceiver circuit/chip with matched antenna structure 30G5; and the system bus 30I which interfaces these components together and provides the necessary addressing, data and control signal pathways supported within the system 30. As such, the micro-computing platform 30G is suitably configured to support and run a local control program 30G2-X on microprocessor 30G3 and memory architecture 30G1, 30G2 which is required and supported by the enterprise-level mobile application 12 and the suite of services supported by the system network 1 of the present invention.

As shown in FIG. 7B, the wireless communication subsystem 30H comprises: an RF-GSM modem transceiver 30H1; a T/X amplifier 30H2 interfaced with the RF-GSM modem transceiver 30H1; and a WIFI interface and a Bluetooth wireless interface 30H3 for interfacing with WIFI and Bluetooth data communication networks, respectively, in a manner known in the communication and computer networking art.

As shown in FIG. 7B, the GPS-tracked and remotely-controllable anti-fire (AF) chemical liquid spray control subsystem 30F comprises: anti-fire chemical liquid supply sensor(s) 30F1 installed in or on the anti-fire chemical liquid supply tank 30B to produce an electrical signal indicative of the volume or percentage of the AF liquid supply tank containing AF chemical liquid at any instant in time, and providing such signals to the AF liquid spraying system control interface 30F4; a power supply and controls 30F2 interfaced with the liquid pump spray subsystem 30C, and also the AF liquid spraying system control interface 30F4; manually-operated spray pump controls interface 30F3, interfaced with the AF liquid spraying system control interface 30F4; and the AF liquid spraying system control interface 30F4 interfaced with the micro-computing subsystem 30G, via the system bus 30I. The flash memory storage 30G2 contains microcode for a control program that runs on the microprocessor 20G3 and realizes the various GPS-specified AF chemical liquid spray control, monitoring, data logging and management functions supported by the system 30.

Specification of GPS-Tracked Autonomously-Driven Drone System Adapted for Spraying Anti-Fire (AF) Liquid on Buildings and Ground Surfaces

FIG. 8A shows a mobile GPS-tracked unmanned airborne system (UAS) or drone 40 adapted for misting and spraying environmentally-clean anti-fire (AF) chemical liquid on exterior building surfaces and ground surfaces in accordance with the principles of the present invention.

As shown, the drone vehicle system 40 comprises: a lightweight airframe 40A0 supporting a propulsion subsystem 40I provided with a set of eight (8) electric-motor driven propellers 40A1-40A8, driven by electrical power supplied by a rechargeable battery module 409, and controlled and navigated by a GPS-guided navigation subsystem 4012; an integrated supply tank 40B supported on the airframe 40A0, and connected to either rechargeable-battery-operated electric-motor driven spray pump, or gasoline/diesel or propane operated motor-driven spray pump, 40C, for deployment on private and public property parcels having building structures; a spray nozzle assembly 40D connected to the spray pump 40C by way of a flexible hose 40E, for misting and spraying the same with environmentally-clean anti-fire (AF) liquid under the control of GPS-specified coordinates defining its programmed flight path when operating to suppress or otherwise fight wild fires.

FIG. 8B shows the GPS-tracked anti-fire liquid spraying system 40 of FIG. 8A as comprising a number of subcomponents, namely: a GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 40F; a micro-computing platform or subsystem 40G interfaced with the GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 40F by way of a system bus 40I; a wireless communication subsystem 40H interfaced to the micro-computing platform 40G via the system bus 40I; and a vehicular propulsion and navigation subsystem 40I employing propulsion subsystem 40I1, and AI-driven or manually-driven navigation subsystem 4012.

As configured in the illustrative embodiment, the GPS-tracked anti-fire liquid spraying system 40 enables and supports (i) the remote monitoring of the spraying of anti-fire (AF) chemical liquid from the system 40 when located at specific GPS-indexed location coordinates, and (ii) the logging of all such GPS-indexed spray application operations, and recording the data transactions thereof within a local database maintained within the micro-computing platform 40G, as well as in the remote network database 9C1 maintained at the data center 8 of the system network 1.

As shown in FIG. 8B, the micro-computing platform 40G comprises: data storage memory 40G1; flash memory (firmware storage) 40G2; a programmable microprocessor 40G3; a general purpose I/O (GPIO) interface 40G4; a GPS transceiver circuit/chip with matched antenna structure 40G5; and the system bus 40I which interfaces these components together and provides the necessary addressing, data and control signal pathways supported within the system 40. As such, the micro-computing platform 40G is suitably configured to support and run a local control program 40G2-X on microprocessor 40G3 and memory architecture 40G1, 40G2 which is required and supported by the enterprise-level mobile application 12 and the suite of services supported by the system network 1 of the present invention.

As shown in FIG. 8B, the wireless communication subsystem 30H comprises: an RF-GSM modem transceiver 40H1; a T/X amplifier 40H2 interfaced with the RF-GSM modem transceiver 40H1; and a WIFI interface and a Bluetooth wireless interface 40H3 for interfacing with WIFI and Bluetooth data communication networks, respectively, in a manner known in the communication and computer networking art.

As shown in FIG. 8B, the GPS-tracked and remotely-controllable anti-fire (AF) chemical liquid spray control subsystem 40F comprises: anti-fire chemical liquid supply sensor(s) 40F1 installed in or on the anti-fire chemical liquid supply tank 30B to produce an electrical signal indicative of the volume or percentage of the AF liquid supply tank containing AF chemical liquid at any instant in time, and providing such signals to the AF liquid spraying system control interface 40F4; a power supply and controls 40F2 interfaced with the liquid pump spray subsystem 40C, and also the AF liquid spraying system control interface 40F4; manually-operated spray pump controls interface 40F3, interfaced with the AF liquid spraying system control interface 30F4; and the AF liquid spraying system control interface 40F4 interfaced with the micro-computing subsystem 40G, via the system bus 40I. The flash memory storage 40G2 contains microcode for a control program that runs on the microprocessor 40G3 and realizes the various GPS-specified AF chemical liquid spray control, monitoring, data logging and management functions supported by the system 40.

Specification of GPS-Tracked Aircraft (i.e. Helicopter) for Spraying Anti-Fire (AF) Liquid on Ground Surfaces

FIG. 9A shows a mobile GPS-tracked manned aircraft (i.e. helicopter) system 50 adapted for misting and spraying environmentally-clean anti-fire (AF) chemical liquid on ground surfaces and over buildings in accordance with the principles of the present invention.

As shown, the aircraft system 50 comprises: a lightweight airframe 50A0 supporting a propulsion subsystem 50I provided with a set of axially-mounted helicopter blades 50A1-50A2 and 50A5, driven by combustion-engine and controlled and navigated by a GPS-guided navigation subsystem 50I2; an integrated supply tank 50B supported on the airframe 50A0, and connected to a gasoline/diesel operated motor-driven spray pump, 50C, for deployment on private and public property parcels having building structures; a spray nozzle assembly 50D connected to the spray pump 50C by way of a hose 50E, for misting and/or spraying the same with environmentally-clean anti-fire (AF) liquid under the control of GPS-specified coordinates defining its programmed flight path when operating to suppress or otherwise fight wild fires.

FIG. 9B shows the GPS-tracked anti-fire liquid spraying system 50 of FIG. 9A as comprising a number of subcomponents, namely: a GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 50F; a micro-computing platform or subsystem 50G interfaced with the GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 50F by way of a system bus 50I; a wireless communication subsystem 50H interfaced to the micro-computing platform 50G via the system bus 50I; and a vehicular propulsion and navigation subsystem 50I employing propulsion subsystem 50I1, and AI-driven or manually-driven navigation subsystem 5012.

As configured in the illustrative embodiment, the GPS-tracked anti-fire liquid spraying system 50 enables and supports (i) the remote monitoring of the spraying of anti-fire (AF) chemical liquid from the system 50 when located at specific GPS-indexed location coordinates, and (ii) the logging of all such GPS-indexed spray application operations, and recording the data transactions thereof within a local database maintained within the micro-computing platform 50G, as well as in the remote network database 9C1 maintained at the data center 8 of the system network 1.

As shown in FIG. 9B, the micro-computing platform 50G comprises: data storage memory 50G1; flash memory (firmware storage) 50G2; a programmable microprocessor 50G3; a general purpose I/O (GPIO) interface 50G4; a GPS transceiver circuit/chip with matched antenna structure 50G5; and the system bus 40I which interfaces these components together and provides the necessary addressing, data and control signal pathways supported within the system 50. As such, the micro-computing platform 50G is suitably configured to support and run a local control program 50G2-X on microprocessor 50G3 and memory architecture 50G1, 40G2 which is required and supported by the enterprise-level mobile application 12 and the suite of services supported by the system network 1 of the present invention.

As shown in FIG. 9B, the wireless communication subsystem 50H comprises: an RF-GSM modem transceiver 50H1; a T/X amplifier 50H2 interfaced with the RF-GSM modem transceiver 50H1; and a WIFI interface and a Bluetooth wireless interface 50H3 for interfacing with WIFI and Bluetooth data communication networks, respectively, in a manner known in the communication and computer networking art.

As shown in FIG. 9B, the GPS-tracked and remotely-controllable anti-fire (AF) chemical liquid spray control subsystem 50F comprises: anti-fire chemical liquid supply sensor(s) 50F1 installed in or on the anti-fire chemical liquid supply tank 50B to produce an electrical signal indicative of the volume or percentage of the AF liquid supply tank containing AF chemical liquid at any instant in time, and providing such signals to the AF liquid spraying system control interface 50F4; a power supply and controls 50F2 interfaced with the liquid pump spray subsystem 50C, and also the AF liquid spraying system control interface 50F4; manually-operated spray pump controls interface 50F3, interfaced with the AF liquid spraying system control interface 50F4; and the AF liquid spraying system control interface 50F4 interfaced with the micro-computing subsystem 50G, via the system bus 50I. The flash memory storage 50G2 contains microcode for a control program that runs on the microprocessor 50G3 and realizes the various GPS-specified AF chemical liquid spray control, monitoring, data logging and management functions supported by the system 50.

Specification of GPS-Tracked Autonomously-Driven Aircraft for Spraying Anti-Fire (AF) Liquid on Building and Ground Surfaces

FIG. 10A shows a mobile GPS-tracked manned all-terrain vehicle (ATV) system 60 adapted for misting and spraying environmentally-clean anti-fire (AF) chemical liquid on ground surfaces in accordance with the principles of the present invention.

As shown, the aircraft system 60 comprises: a lightweight frame/chassis 60A0 supporting a propulsion subsystem 60I provided with a set of wheels 60A1-60A4, driven by combustion-engine, and controlled and navigated by a GPS-guided navigation subsystem 6012; an integrated supply tank 60B supported on the frame 60A0, and connected to a gasoline/diesel operated motor-driven spray pump, 60C, for deployment on private and public property parcels; a spray nozzle assembly 60D connected to the spray pump 60C by way of a hose 60E, for misting and/or spraying the same with environmentally-clean anti-fire (AF) liquid under the control of GPS-specified coordinates defining its programmed flight path when operating to suppress or otherwise fight wild fires.

FIG. 10B shows the GPS-tracked anti-fire liquid spraying system 60 of FIG. 10A as comprising a number of subcomponents, namely: a GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 60F; a micro-computing platform or subsystem 60G interfaced with the GPS-tracked and remotely-monitored AF chemical liquid spray control subsystem 60F by way of a system bus 60I; a wireless communication subsystem 60H interfaced to the micro-computing platform 60G via the system bus 50I; and a vehicular propulsion and navigation subsystem 60I employing propulsion subsystem 6011, and AI-driven or manually-driven navigation subsystem 6012.

As configured in the illustrative embodiment, the GPS-tracked anti-fire liquid spraying system 60 enables and supports (i) the remote monitoring of the spraying of anti-fire (AF) chemical liquid from the system 60 when located at specific GPS-indexed location coordinates, and (ii) the logging of all such GPS-indexed spray application operations, and recording the data transactions thereof within a local database maintained within the micro-computing platform 60G, as well as in the remote network database 9C1 maintained at the data center 8 of the system network 1.

As shown in FIG. 10B, the micro-computing platform 60G comprises: data storage memory 60G1; flash memory (firmware storage) 60G2; a programmable microprocessor 60G3; a general purpose I/O (GPIO) interface 60G4; a GPS transceiver circuit/chip with matched antenna structure 60G5; and the system bus 60I which interfaces these components together and provides the necessary addressing, data and control signal pathways supported within the system 60. As such, the micro-computing platform 60G is suitably configured to support and run a local control program 60G2-X on microprocessor 60G3 and memory architecture 60G1, 60G2 which is required and supported by the enterprise-level mobile application 12 and the suite of services supported by the system network 1 of the present invention.

As shown in FIG. 10B, the wireless communication subsystem 50H comprises: an RF-GSM modem transceiver 60H1; a T/X amplifier 60H2 interfaced with the RF-GSM modem transceiver 60H1; and a WIFI interface and a Bluetooth wireless interface 60H3 for interfacing with WIFI and Bluetooth data communication networks, respectively, in a manner known in the communication and computer networking art.

As shown in FIG. 10B, the GPS-tracked and remotely-controllable anti-fire (AF) chemical liquid spray control subsystem 60F comprises: anti-fire chemical liquid supply sensor(s) 60F1 installed in or on the anti-fire chemical liquid supply tank 60B to produce an electrical signal indicative of the volume or percentage of the AF liquid supply tank containing AF chemical liquid at any instant in time, and providing such signals to the AF liquid spraying system control interface 60F4; a power supply and controls 60F2 interfaced with the liquid pump spray subsystem 60C, and also the AF liquid spraying system control interface 60F4; manually-operated spray pump controls interface 60F3, interfaced with the AF liquid spraying system control interface 60F4; and the AF liquid spraying system control interface 60F4 interfaced with the micro-computing subsystem 60G, via the system bus 60I. The flash memory storage 60G2 contains microcode for a control program that runs on the microprocessor 60G3 and realizes the various GPS-specified AF chemical liquid spray control, monitoring, data logging and management functions supported by the system 60.

Specification of an Exemplary Network Database Schema for Supporting the System Network of the Present Invention and GPS-Specified Operations Involving the Spraying of Anti-Fire (AF) Liquid on GPS-Specified Ground, Property and Building Surfaces in Regions at Risk Prior to and During the Outbreak of Wild Fires

FIG. 11 shows an exemplary schema for the network database (RDBMS) 9C1 supported by the system network of the present invention, showing the primary enterprise level objects supported in the database tables created in the network database 9C using the schema, and the relationships that are specified or indicated. This exemplary database schema is for supporting the system network of the present invention and GPS-specified operations involving the spraying of anti-fire (AF) liquid on GPS-specified ground, property and building surfaces in regions at risk prior to and during the outbreak of wild fires.

As shown in FIG. 11 , the exemplary database schema for the system network 1 includes a number of high-level enterprise objects such as, for example: Users, with properties including User ID, Residence, Age, User Class (e.g. Wild Fire Management Administrator, Wild Fire Spray Applicator, Real Property Owner, Home Owner, Business Owner, Property Owner, Resident, etc.), and Pets; Real Property, with properties including Ownership/Lease, Location, Buildings, GPS Addresses, County, State; Vehicles, with properties such as Model, Year, Brand, Registered Owner; Water Crafts, with properties Model, ID # etc.; Anti-Fire Chemical Liquid Supplies, with properties Manufacturer, Location, Quantity, Date Delivered; Anti-Fire (AF) Liquid Spraying Aircraft Systems, with properties Manufacturer, Model, ID #; Anti-Fire Liquid Spraying Ground Systems, including Manufacturer, Model, ID #; Portable Anti-Fire Liquid Spraying Systems; Anti-Fire (AF) Chemical Liquid Spray Application Orders, including Location, ID #; Anti-Fire Chemical Liquid Spray Application Reports, with properties such as State, County, GPS Addresses; and Weather Data, with properties State, County, and GPS Addresses.

Specification of Exemplary Graphical User Interfaces Supported on the Mobile Application Deployed on System Network of the Present Invention, for the Purpose of Delivering the Various Services Supported on the System Network

FIG. 12 illustrates an exemplary wire-frame model of a graphical user interface (GUI) 13 of the mobile application 120 for use by registered users (e.g. property parcel owners, contractors and/or agents, and other stakeholders on the system network) to request and receive services supported by the system network of the present invention. As shown in this exemplary GUI screen 13, supports a number of pull-down menus under the titles: messages 13A, where the user can view messages sent via messaging services supported by the application; maps 13B, where wild fires have been identified and mapped, tracked and ranked in terms of risk to the user and associated property; and tasks 13C, where AF liquid spray tasks have been have been scheduled, have been completed, or are in progress, by the user.

FIG. 12A shows an exemplary graphical user interface supported by the mobile application 12 showing a user updating the registration profile as a task on the system network. The GUI screen is accessed and delivered to LCD screen of the mobile computing device 11 when the user selects the Tasks menu to display a menu of commands, and then selects the Update command from the command menu. During this service, the user can update various information items relating to the user profile, such as, name and address, contact information (e.g. email and SMS number), property parcel linked to one's profile, and GPS-tracked spray system deployed or assigned to the user and/or property parcel(s).

FIG. 12B shows an exemplary graphical user interface supported by the mobile application 12 showing a user receiving a message “notice of request to wild-fire spray protect a property parcel” (via email, SMS messaging and/or push-notifications) issued from the command center 19 to spray GPS-specified private property parcel(s) with clean anti-fire (AF) chemical liquid and registered GPS-tracked spray equipment.

FIG. 12C shows an exemplary graphical user interface supported by the mobile application 12 showing a user receiving a notice of order (via email, SMS messaging and/or push-notifications) to wild-fire spray-protect GPS-specified public property parcel(s) with clean anti-fire (AF) liquid to create and maintain a GPS-specified public firebreak (e.g. Firebreak No. 120).

FIG. 12D shows an exemplary graphical user interface supported by the mobile application showing a user requesting a refill of clean anti-fire (AF) chemical liquid for supply to GPS-specified spray equipment registered on the system network. The user selects the Tasks menu to display a set of commands, and then selects the Refill command from the displayed command menu. The user confirms the refill order and when ready selects the Send Request command from the display screen, sending the command to the command center 19 and related data center 8 for processing and fulfillment. All operations are logged and tracked in the system network database 9C1 shown in FIG. 4 .

In the illustrative embodiment, the mobile application 12 on mobile computing device 11 supports many functions to provide many services: (i) sends automatic notifications from the command center 19 to home/business owners with the mobile application 12, instructing them to spray their real property and home/building at certain times with anti-fire (AF) liquid contained in the tanks of GPS-tracked AF liquid spraying systems 20, 30, 40, 40, 50 and 60; (ii) automatically monitors consumption of sprayed AF-liquid and generate auto-replenish order (via its onboard GSM-circuits) so as to achieve compliance with the home/neighborhood spray defense program, and report AF chemical liquid levels in each home-owner tank; and (iii) shows status of wild fire risk in the region, and actions to the taken before wild fire outbreak.

FIG. 13 shows an exemplary graphical user interface 13′ supported by the mobile application 12 configured for use by command center administrators to issue wild-fire protection orders, plan wild-fire protection tasks, generate wild-fire and protection reports, and send and receive messages to users on the system network, to carry out a wild fire suppression and management program in the region where the system network is deployed. As shown, GUI screen 13′ supports a number of pull-down menus under the titles: Messages 13A′, where project administrator and spray technicians can view messages sent via messaging services supported by the application; Maps 13B′, where wild fires have been identified, tracked, and ranked in terms of risk to certain regions at a given moment in time; Planning 13C′, wherein plans have been have been made to fight wild fires using the methods described in FIGS. 17 through 25B, status of specific plans, which one are in progress; and Reports 13D′, where reports are issued to the mobile application 12 running on mobile client systems 11 in operable communication with the web, application and database servers 9A, 9B and 9C at the data center 8, supported by the system network 1.

FIG. 13A shows an exemplary graphical user interface supported by the mobile application configured for use by command center administrators to issue wild-fire protection orders using the system network of the present invention. As shown, the user selects the Planning menu and displays a set of planning commands, and then selects the Property command, where the user is then given the choice to select one or more parcels of property in a given region, and then select an Action (e.g. Wild Fire Spray Protect). The users selects the property parcel(s), and then the required Action (i.e. Wild Fire Spray Protect), and Order is set up for the command center action. When the command center selects execute from the menu, the system network issues the order and sends notice of orders to all property parcel owners or agents to oversee the immediate spraying of the GPS-specified property parcels with clean anti-fire (AF) chemical liquid supply to the property owners or agents as the case may be.

FIG. 13B shows an exemplary graphical user interface supported by the mobile application 12 configured for use by command center administrators to issue wild-fire protection orders involving the creation and maintenance of a clean AF-based chemical firebreak, as illustrated in FIG. 18 , for example, using the methods of the present invention described herein. As shown, the administrator selects the Planning menu, and displays a menu of Planning commands, from which the user selects Firebreaks. In the case example shown in FIG. 13B, the administrator issues an Order to apply or rather practice the dual-region clean AF chemical firebreak method illustrated in FIG. 18 , at GPS-specified coordinates GPS LAT-X/LONG-Y using AF chemical liquid misting and spraying airborne operations. As shown the order will specify the deployment of specific GPS-tracked AF spray vehicle systems, and identify them by system ID #. The order may also identify or request users (e.g. pilots) assigned to the AF chemical firebreak project/task.

FIG. 13C shows an exemplary graphical user interface supported by mobile application 12 configured for use by command center administrators to order the creation and/or maintenance of a GPS-specified clean AF-based chemical firebreak on one or more public/private property parcels. As shown, the administrator selects the Planning menu, and displays a menu of Planning commands, from which the user selects Firebreaks. In the case example shown in FIG. 13C, the administrator issues an Order to practice the Wild Fire Spray Protect Method alongside one or more parcels of public property, which may be a long strip of land/brush alongside or near a highway. The method may be the AF chemical firebreak method as illustrated in the FIG. 22 and described in FIGS. 23A, 23B and 23C, at GPS-specified coordinates GPS LAT-X/LONG-Y using ground-based AF chemical liquid spraying operations. As shown, the order will specify the deployment of specific GPS-tracked AF spray vehicle systems, and identify them by system ID #. The order may also identify or request users (e.g. drivers) assigned to the AF chemical firebreak project/task. Alternatively, other methods disclosed in FIGS. 20 through 21C and FIGS. 24, 25A and 25B.

FIG. 13D shows an exemplary graphical user interface for mobile application configured used by command center administrators to receive messages from users including property owners and contractors, requesting refills for clean anti-fire (AF) chemical liquid for GPS-specified spray system equipment. While the system network 1 AF chemical liquid refills

FIG. 14 shows an exemplary fire hazard severity zone (FHSZ) map generated by the CAF FIRE™ System in state responsibility areas of the State of California. Such maps can be used by the system network 1 to inform the strategic application of environmentally-clean anti-fire (AF) liquid spray using the system network of the present invention. Such maps also can be displayed on the mobile application 12 to provide greater awareness of risks created by wild fires in a specific region, at certain moments in time.

Specification of an Exemplary Anti-Fire (AF) Spray Protection Map Generated by the System Network of the Present Invention

FIG. 15 shows an exemplary GPS-specified anti-fire (AF) chemical liquid spray protection map generated by the system network 1, showing properties, houses and buildings that were sprayed, and not-sprayed, with state/county-issued anti-fire liquid as of report date, 15 Dec. 2017. The system network will periodically update these AF chemical liquid spray protection maps (e.g. every 5 minutes or less) for display to users and neighbors to see whose property/land parcels and homes/building have been spray protected with anti-fire (AF) chemical liquid (e.g. Hartindo AF31 anti-fire chemical liquid), and whose parcels and home/buildings have not been AF-spray protected against wild fires, so that they can or may volunteer to lend a helping hand in spray protecting their neighbors properties as time and anti-fire chemical supplies allow, to provide a stronger defense against one or more wild fires raging towards their neighborhood.

In accordance with the principles of the present invention, the application servers 9B supported by the system network 1 will automatically generate anti-fire (AF) chemical liquid spray-protection task reports, as illustrated in FIG. 16 , based on the analysis of spray-protection maps as shown in FIG. 15 , and based on many other kinds of intelligence collected by the system, and analyzed by human analysts, as well as artificial intelligence (AI) expert systems. Based on such automated intelligence efforts, the application servers 9B will generate periodically, and as needed, AF chemical liquid (AFCL) Spray Command Program files containing GPS/Time-Frame-indexed commands and instructions that are wirelessly transmitted to assigned GPS-tracked anti-fire (AF) chemical liquid spraying systems 30, 40, 50 and 60, so that the operators of such GPS-tracked AF liquid spraying systems will know when and where to mist and/or spray AF chemical liquid over and one certain GPS-specified properties, in their effort to defend against the threat of wild fires.

The AFCL Spray Command Program files, containing GPS-indexed commands and instructions, generated by the application servers 9B are transmitted over the system network 1 to the numerous deployed GPS-tracked AF liquid spraying systems 30, 40, 50 and 60, so as to orchestrate and choreograph the spray application of clean anti-fire (AF) chemical liquid over GPS-specified properties, before and during the presence of wild fires, so as to implement an orchestrated strategic and collective defense against wild fires that break out for various reasons, threatening states, counties, towns, neighborhoods homes, business, and human and animal life.

In some embodiments, the application servers 9B will generate and issue AFCL Spray Command Program files that are transmitted to specific GPS-tracked AF liquid spraying systems 30, 40, 50 and 60, and containing automated instructions (i.e. commands) on when and where (i.e. in terms of time frame and GPS-specified coordinates) the GPS-tracked AF liquid spraying systems should automatically apply, via spraying operations, clean AF chemical liquid on GPS-specified property during their course of movement over land. During such spraying operations, the system network 1 will automatically meter, dispense and log how much clean AF chemical liquid has been sprayed over and on certain GPS-specified properties. Real-time wind-speed measurements can be made and used to compensate for spraying operations in real-time, as may be required under certain weather conditions.

In other embodiments, the application servers 9B will generate and issue AFCL Spray Command Program files that are transmitted to other GPS-tracked AF liquid spraying systems 30, 40, 50 and 60, providing automated instructions (i.e. commands) on when and where the GPS-tracked AF liquid spraying systems should spray-apply clean AF chemical liquid on GPS-specified property during course of movement over land, but allowing the human operator to override such spraying instructions, and compensate and ensure greater accuracy, using human operator skill and judgment during spraying operations. While such spraying operations, the system will automatically meter, log and record all dispensed AF chemical liquid sprayed over and over certain GPS-specified properties under the supervision and control of the human operator.

Specification of an Exemplary Anti-Fire Spray Protection Task Report Generated by the System of the Present Invention

FIG. 16 shows an exemplary GPS-specified anti-fire spray protection task report generated by the system network 1 for state/county xxx on 15 Dec. 2017, indicating which properties on what streets, in what town, county, state, requires the reapplication of AF chemical liquid spray treatment in view of factors such as weather (e.g. rainfall, sunlight) and passage of time since last spray application. Such task reports will be transmitted by the command center 19 to registered users, along with an SMS and/or email message to attend to the AF spray task, so the requested user will promptly spray protect their land parcels and home with clean AF chemical liquid, as conditions require or suggest, using the mobile/portable GPS-tracked AF liquid spraying system 20 assigned to the property owner, and deployed over the system network 1.

As contracted AF-spray operators, and home owners alike, protect properties and homes using the GPS-tracked AF liquid spraying systems (20, 30, 40, 50 and 60), the system network 1 automatically receives GSM or other RF-based signals transmitted from the GPS-tracked anti-fire (AF) chemical liquid spraying systems, indicating that certain amounts of AF chemical liquid has been dispensed and sprayed from the system onto GPS-specified property. Notably, the amounts of AF chemical liquid dispensed and sprayed from the system over and onto GPS-specified property should closely match the amounts requested in the task report transmitted to the user, to achieve the AF spray protection task directed by AI-driven management processes supported by the wild fire suppression system network of the present invention.

Specification of New and Improved Wild Fire Suppression Methods in Accordance with Principles of the Present Invention

Having described the various GPS-tracked anti-fire (AF) chemical liquid spraying systems of the illustrative embodiments 20, 30, 40, 50 and 60, shown in the Figure Drawings, and the various functions supported by the mobile application 12 supported by the data center 8 of the system network 1, it is appropriate at this juncture to now described the various new and improved wild fire suppression methods in accordance with principles of the present invention, each involving GPS-guided spray application of clean anti-fire (AF) chemical liquid having a chemistry that works to break a wild fire by interfering with the free-radicals produced during the combustion phase of a ranging wild fire. The benefits and advantages provided by such new and improved methods will become apparent hereinafter.

Specification of a Method of Suppressing a Wild Fire Raging Across a Region of Land in the Direction of the Prevailing Winds

FIG. 17 shows a plan view of a wild fire 70 emerging from a forest region 71A and approaching a neighboring town 72 surrounded by other forest regions 71B, 71B and 71C, and moving in the direction determined by prevailing winds, indicated by a pair of bold arrows. This example closely resembles the pathway of many wild fires recently destroying countless acres of land (i.e. real property) in the State of California in 2017.

FIG. 18 illustrates the various steps involved in carrying out the method of suppressing a wild fire raging across a region of land. Specifically, the method involves forming a multi-stage anti-fire chemical fire-break system illustrated in FIG. 18 using the remotely-managed GPS-controlled application of both anti-fire (AF) liquid mist streams and AF chemical liquid spray streams from ground and air based GPS-tracked anti-fire (AF) liquid spray vehicles, as illustrated in FIGS. 7A, 7B and 9A, 9B, for example.

As illustrated in FIG. 18 , the method generally involves: (a) applying, prior to the wild fire reaching the specified target region of land 74, a low-density anti-fire (AF) liquid mist stream in advance of the wild fire 75 so as to form a fire stall region 76, while providing a non-treated region 77 of sufficient size between the front of the wild fire 75 approaching the target region of land 73 and the fire stall region 76; and (b) applying a high-density anti-fire (AF) liquid spray stream in advance of the wild fire 75 to form a fire break region 74 beyond and contiguous with the fire stall region 76, and also continuous with the target region 73 to be protected from the wild fire.

As illustrated in FIG. 18 , the fire stall region 76 is formed before the wild fire reaches the fire stall region 76. The fire stall region 76 operates to reduce the free-radical chemical reactions raging in the wild fire 75. This fire stall region 76 helps to reduce the destructive energy of the wild fire by the time the wild fire reaches the fire break region 74, and enabling the fire break region 74 to operate and significantly break the free radical chemical reactions in the wild fire 75 when the wild fire reaches the fire break region 74. This helps to suppress the wild fire 75 and protect the target region of land 73.

FIGS. 19A and 19B describe the method of suppressing a wild fire raging towards a target region of land 73 (and beyond) in a direction determined by prevailing winds and other environmental and weather factors, as illustrated in FIG. 18 . Typically, the system used to practice this method of the present invention will employ a centralized GPS-indexed real-property/land database system 7 shown in FIG. 4 containing GPS-indexed maps of all land regions under management and fire-protection, developed using methods, equipment and services known in the GPS mapping art. Such GPS-indexed maps will contain the GPS coordinates for the vertices of each and every parcel in any given state, county and town in the country in which system is deployed. As shown in FIG. 4 , this central GPS-indexed real property database 7 will be operably connected to the TCP/IP infrastructure 10 of the Internet, and accessible by system network 1 of the present invention.

As indicated at Block A in FIG. 19A, prior to the wild fire reaching the specified target region of land, a GPS-tracked AF spray vehicle 50 as shown for example in FIG. 9A applies a low-density anti-fire (AF) liquid mist 80 in advance of the wild fire so as to form a fire stall region 76 while providing a non-treated region 77 of sufficient size between the front of the wild fire approaching the target region of land 73 and the fire stall region 76. The fire stall region 76 is formed by a first GPS-guided aircraft system flying over the fire stall region during multiple passes and applying the low-density AF chemical liquid mist 80 over the fire stall region 76. The non-treated region 77 is defined by a first set of GPS coordinates {GPS₁(x,y)} and, the fire stall region 76 is defined by a second set of GPS coordinates {GPS₂(x,y)}. Each of these regions are mapped out using global positioning system (GPS) methods, the GPS-indexed land database system 7, drone-type aircraft systems as shown in FIG. 8A, and space-based land-imaging satellites 14 having multi-spectral imaging capabilities, and operably connected to the infrastructure of the Internet. When used alone and/or together, these systems are capable of capturing real-time intelligence on the location and spread of a particular wild fire, its direction of propagation, intensity and other attributes. This captured data is provided to application servers in the data center 8 which, in turn, generate GPS coordinates determining the planned pathways of the GPS-traced AF chemical liquid spraying/misting aircraft systems, to provide the anti-fire protection over the GPS-indexed fire stall region 76 and GPS-specified non-treated region 75, as described in greater detail below.

As indicated at Block B in FIG. 19A, a second GPS-tracked AF spray vehicle as shown in FIG. 9A applies a high-density anti-fire (AF) liquid spray 81 over the land in advance of the wild fire to form a GPS-specified fire break region 74 beyond and contiguous with the GPS-specified fire stall region 76. The fire break region 74 is formed by the second GPS-guided aircraft flying over the fire break region 74 during multiple passes and applying the high-density AF chemical liquid spray 81 over the fire break region 74. The fire break region 74 is defined by a third set of GPS coordinates {GPS₃(x,y)} mapped out using global positioning system (GPS) methods, the GPS-indexed land database system 7, drone-type aircraft systems as shown in FIG. 8A, and/or space-based land-imaging satellites 14 having multi-spectral imaging capabilities, and operably connected to the infrastructure of the Internet. When used alone and/or together, these systems are capable of capturing real-time intelligence on the location and spread of a particular wild fire, its direction of propagation, intensity and other attributes. This captured data is provided to application servers in the data center 8 which, in turn, generate GPS coordinates determining the planned pathways of the GPS-traced AF chemical liquid spraying/misting aircraft systems, to provide the anti-fire protection over GPS-specified fire break region 74, as described in greater detail below.

As indicated at Block C in FIG. 19B, the fire stall region 76 is formed before the wild fire 75 reaches the fire stall region 76, and operates to reduce the free-radical chemical reactions raging in the wild fire so as to reduce the destructive energy of the wild fire by the time the wild fire 75 reaches the fire break region 74, and enabling the fire break region 74 to operate and significantly break the free radical chemical reactions in the wild fire 75 when the wild fire reaches the fire break region 74, and thereby suppress the wild fire 75 and protect the target region of land 73 and beyond.

Specification of a Method of Reducing the Risks of Damage to Private Property Due to Wild Fires by Managed Application of Anti-Fire (AF) Liquid Spray

FIG. 20 illustrates a method of reducing the risks of damage to private property due to wild fires by managed application of anti-fire (AF) liquid spray. FIGS. 21A, 21B and 21C illustrates a method of reducing the risks of damage to private property due to wild fires by managed application of anti-fire (AF) liquid spray. Typically, this method is carried out using the system network of FIG. 4 and any one or more of the GPS-tracked anti-fire (AF) liquid spray vehicle systems 14A-14D represented in FIG. 4 and shown in FIGS. 6A, 6B, 7A, 7B, 8A, 8B, 9A, 9B, and 10A, 10B.

As indicated at Block A in FIG. 21A, the system registers each GPS-specified parcel of private real property in a specified County and State, which may or may not have buildings constructed thereon, and identifying the owner and tenants, as well as all pets, vehicles and watercrafts associated with the registered parcel of private property. Typically, the system will request the address of the property parcel, and will automatically determine its GPS coordinates that specify the vertices of the parcel using databases, and data processing methods, equipment and services, known in the GPS mapping art.

As indicated at Block B in FIG. 21A, the system collects intelligence relating to the County, risks of wild fires in the surrounding region, and historical data maintained in a network database, and generating GPS-specified anti-fire (AF) spray protection maps and task reports for execution.

As indicated at Block C in FIG. 21A, an AF chemical liquid spraying system is provided to a GPS-specified location for spraying one or more registered parcels of private property with AF chemical liquid spray.

As indicated at Block D in FIG. 21A, a supply of AF chemical liquid spray is provided to the GPS-specified location of the AF chemical liquid spraying system.

As indicated at Block E in FIG. 21A, the AF chemical liquid spraying system is provided with the supply of AF chemical liquid,

As indicated at Block F in FIG. 21B, based on the GPS-specified anti-fire (AF) spray protection maps and task reports, the system issues orders to the private property owner, or its contractor, to apply AF chemical liquid spray on the private property using the AF chemical liquid spraying system.

As indicated at Block G in FIG. 21B, the private property owner executes the order and applies AF chemical liquid spray on the private property using the AF chemical liquid spraying system, and the system remotely monitors the consumption and application of AF chemical liquid at the private property on a given time and date, and automatically records the transaction in the network database 9C prior to the arrival and presence of wild fire in the region.

As indicated at Block H in FIG. 21B, the system updated the records in the network database associated with each application of AF chemical liquid spray on a GPS-specified parcel of private property.

As indicated at Block I in FIG. 21B, the system scheduled the next application of AF chemical liquid spray on the GPS-specified parcel of private property, factoring weather conditions and the passage of time.

As indicated at Block J in FIG. 21B, the system issues another order to the GPS-specified parcel of private property to re-apply AF chemical liquid spray on the private property to maintain active wild fire protection.

As indicated at Block K in FIG. 21C, the property owner executes (i.e. carries out) the order to reapply AF chemical liquid spray on the parcel of private property using the AF chemical liquid spraying system, and the system remotely monitors the application of AF chemical liquid at the private property on a given time and date, and records this transaction in the network database 9C.

As indicated at Block L in FIG. 21C, the system updates records on AF chemical liquid spray application in the network database 9C associated with reapplication of AF chemical liquid on the parcel of private property.

As indicated at Block M in FIG. 21C, the system schedules the next application of AF chemical liquid spray on the parcel of private property, factoring weather conditions and the passage of time.

Specification of a Method of Reducing the Risks of Damage to Public Property Due to Wild Fires, by Managed Spray Application of AF Liquid to Ground Cover and Building Surfaces Prior to the Arrival of Wild Fires

FIG. 22 illustrates a method of reducing the risks of damage to public property due to wild fires, by managed spray application of AF chemical liquid to ground cover and building surfaces prior to the arrival of wild fires. FIGS. 23A, 23B and 23C illustrate a method of reducing the risks of damage to public property due to wild fires by managed application of anti-fire (AF) liquid spray. Typically, this method is carried out using the system network of FIG. 4 and any one or more of the GPS-tracked anti-fire (AF) liquid spray vehicle systems 14A-14D represented in FIG. 4 and shown in FIGS. 6A, 6B, 7A, 7B, 8A, 8B, 9A, 9B, and 10A, 10B.

As indicated at Block A in FIG. 23A, each GPS-specified parcel of public real property in a specified County and State is registered with the system. Such parcels of property may or may not have buildings constructed thereon. As part of registration with the system network 1, supported by the network database 9C, it is necessary to identify the owner and tenants, as well as all pets, vehicles and watercrafts associated with the registered parcel of public property. Typically, the system will request the address of the property parcel, and will automatically determine its GPS coordinates that specify the vertices of the parcel using databases, and data processing methods, equipment and services, known in the GPS mapping art.

As indicated at Block B in FIG. 23A, the system collects various kinds of intelligence relating to the County, risks of wild fires in the surrounding region, and historical weather and related data maintained in a network database 9C, and generates GPS-specified anti-fire (AF) spray protection maps and task reports for review and execution, along with GPS-specified spray plans (e.g. flight plans) for GPS-tracked anti-fire (AF) liquid spray vehicle systems 30 and 60, and GPS-specified spray plans.

As indicated at Block C in FIG. 23A an AF chemical liquid spraying system is provided to a GPS-specified location for spraying one or more registered parcels of public property with AF chemical liquid spray.

As indicated at Block D in FIG. 23A, a supply of AF chemical liquid spray is provided to the registered location of the AF chemical liquid spraying system.

As indicated at Block E in FIG. 23A, the AF chemical liquid spraying system is filled with the provided supply of AF chemical liquid.

As indicated at Block F in FIG. 23B, based on the anti-fire (AF) spray protection maps and task reports, the system issues orders to the public property owner, or its contractor, to apply AF chemical liquid spray on the public property using the AF chemical liquid spraying system 60.

As indicated at Block G in FIG. 23B, the public property owner executes the order and applies AF chemical liquid spray on the public property using the AF chemical liquid spraying system, and the system remotely monitors the consumption and application of AF chemical liquid at the public property on a given time and date, and automatically records the transaction in the network database prior to the presence of wild fire in the region.

As indicated at Block H in FIG. 23B, the system updates records in the network database 9C associated with each application of AF chemical liquid spray on a GPS-specified parcel of public property.

As indicated at Block I in FIG. 23B, the system schedules the next application of AF chemical liquid spray on the GPS-specified parcel of public property, factoring weather conditions and the passage of time.

As indicated at Block J in FIG. 23B, the system issues another order to the GPS-specified parcels of public property to re-apply AF chemical liquid spray on the public property to maintain active fire protection.

As indicated at Block K in FIG. 23C, the property owner executes the order to reapply AF chemical liquid spray on the GPS-specified parcels of public property using the AF chemical liquid spraying system, and the system remotely monitors the application of AF chemical liquid at the public property on a given time and date, and records this transaction in the network database 9C.

As indicated at Block L in FIG. 23C, the system updates records on AF chemical liquid spray application in the network database 9C associated with reapplication of AF chemical liquid on the GPS-specified parcels of public property.

As indicated at Block M in FIG. 23C, the system schedules the next application of AF chemical liquid spray on the GPS-specified parcels of public property, factoring weather conditions and the passage of time.

Specification of a Method of Remotely Managing the Application of Anti-Fire (AF) Liquid Spray to Ground Cover and Buildings so as to Reduce the Risks of Damage Due to Wild Fires

FIG. 24 is a graphical illustration showing a method of remotely managing the application of anti-fire (AF) liquid spray to ground cover and buildings so as to reduce the risks of damage due to wild fires. FIGS. 25A and 25B describes the high level steps carried out by the method in FIG. 24 to reduce the risks of damage due to wild fires. Typically, this method is carried out using the system network of FIG. 4 and any one or more of the GPS-tracked anti-fire (AF) chemical liquid spray vehicle systems 14A-14D represented in FIG. 4 and shown in FIGS. 6A, 6B, 7A, 7B, 8A, 8B, 9A, 9B, and 10A, 10B.

As indicated at Block A in FIG. 25A, the system registers each GPS-specified parcel of real property in a specified County and State, which may or may not have buildings constructed thereon, and identifying the owner and tenants, as well as all pets, vehicles and water crafts associated with the registered parcel of real property. Typically, the system will request the address of the property parcel, and will automatically determine (or estimate) its GPS coordinates that specify the vertices of the parcels using databases, and data processing methods, equipment and services, known in the GPS mapping art. The GPS address of each parcel will be stored in the centralized GPS-indexed land database system 7 shown in FIG. 4

As indicated at Block B in FIG. 25A, the system collects intelligence relating to the County, risks of wild fires in the surrounding region, and historical data maintained in a network database, and generates GPS-specified anti-fire (AF) spray protection maps and task reports for execution.

As indicated at Block C in FIG. 25A, an AF chemical liquid spraying system is provided to a GPS-specified location for spraying the GPS-specified parcels of real property with AF chemical liquid spray.

As indicated at Block D in FIG. 25A, a supply of AF chemical liquid spray is provided to the GPS-specified location of the AF chemical liquid spraying system.

As indicated at Block E in FIG. 25A, the AF chemical liquid spraying system is filled with the provided supply of AF chemical liquid.

As indicated at Block F in FIG. 25B, prior to the arrival of a wild fire to the region, and based on the anti-fire (AF) spray protection maps generated by the system, the system issues a request to property owners, or their registered contractors, to apply AF chemical liquid spray on GPS-specified properties using deployed AF chemical liquid spraying systems.

As indicated at Block G in FIG. 25B, in response to the issued request, the property owner or contractor thereof applies AF chemical liquid spray on the real property using the AF chemical liquid spraying system, and the system remotely monitors the consumption and application of the AF chemical liquid on the property on a given date, and automatically records the transaction in the network database.

As indicated at Block H in FIG. 25B, the system updates records in the network database associated with each application of AF chemical liquid spray on one or more GPS-specified parcels of real property.

In the illustrative embodiment, Hartindo AF31 Total Fire Inhibitor (from Hartindo Chemicatama Industri of Jakarta, Indonesia http://hartindo.co.id, or its distributor Newstar Chemicals of Malaysia) is used as a clean anti-fire (AF) chemical liquid when practicing the present invention. A liquid dye of a preferred color from Sun Chemical Corporation http://www.sunchemical.com can be added to Hartindo AF31 liquid to help visually track where AF chemical liquid has been sprayed during the method of wild fire suppression. However, in some applications, it may be desired to maintain the AF chemical liquid in a clear state, and not employ a colorant. Also, the clinging agent in this AF chemical liquid formulation (i.e. Hartindo AF31 liquid) will enable its chemical molecules to cling to the surface of combustible materials, including vegetation, so that it is quick to defend and break the combustion phase of fires (i.e. interfere with the free radicals driving combustion).

Specification of the Method of Qualifying Real Property for Reduced Property Insurance, Based on Verified Spray-Based Clean Anti-Fire (AF) Chemical Liquid Treatment, Prior to Presence of Wild Fires, Using the System Network of the Present Invention

FIG. 26 describes the method of qualifying real property for reduced property insurance, based on verified spray-based clean anti-fire (AF) chemical liquid treatment prior to presence of wild fires, using the system network of the present invention 1 described in great technical detail hereinabove.

As indicated at Block A in FIG. 26 , a clean anti-fire (AF) chemical liquid is periodically sprayed over the exterior surfaces of a wood-framed building and surrounding real property to provide Class-A fire-protection to the property in the face of an approaching wild fire.

As indicated at Block B in FIG. 26 , the spray-based Class-A fire protection treatment is verified and documented using captured GPS-coordinates and time/date stamping data generated by the GPS-tracked AF-liquid spraying system (20, 30, 40, 50 and/or 60) deployed on the system network 1 and used to apply fire protection treatment.

As indicated at Block C in FIG. 26 , the spray protection treatment data, generated by the GPS-tracked anti-fire (AF) liquid spraying system used to apply the spray-based class-a fire protection treatment, is wirelessly transmitted to the central network database, to update the central network database 9C1 on the system network.

As indicated at Block D in FIG. 26 , a company underwriting property insurance for the wood-framed building accesses the central network database 9C1 on the system network 1, to verify the database records maintained for each spray-based Class-A fire-protection treatment relating to the property and any wood-framed buildings thereon, to qualify the property/building owner for lower property insurance premiums, based on the verified Class-A fire-protection status of the sprayed property/building.

As indicated at Block E in FIG. 26 , upon the outbreak of a wild fire about the insured wood-framed building/property, the local fire departments can use the mobile application 12 designed to command center administrators, a provided with suitable filters and modifications, to instantly and remotely assess the central network database 9C1, so as to quickly determine and identify the Class-A fire-protected status of the property and any wood-framed buildings thereon by virtue of timely clean anti-fire (AF) chemical liquid application on the property, and advise fireman fighting and managing wild fires that the Property has been properly defended against wild fire.

By virtue of this method of the presence invention described above, it is now possible to better protect real property and buildings against wild fires when using the system network of the present invention 1, and at the same time, for property insurance underwriters to financially encourage and incentivize property owners to comply with the innovative clean anti-fire (AF) chemical liquid spray programs disclosed and taught herein that improve the safety and defense of neighborhoods against the destructive energy carried by wild fires.

Modifications to the Present Invention which Readily Come to Mind

The illustrative embodiments disclose the use of clean anti-fire chemicals from Hartindo Chemicatama Industri, particular Hartindo AAF31, for clinging to the surfaces of wood, lumber, and timber, and other combustible matter, wherever wild fires may travel. However, it is understood that alternative clean anti-fire chemical liquids may be used to practice the various wild fire suppression methods according to the principles of the present invention.

These and other variations and modifications will come to mind in view of the present invention disclosure.

While several modifications to the illustrative embodiments have been described above, it is understood that various other modifications to the illustrative embodiment of the present invention will readily occur to persons with ordinary skill in the art. All such modifications and variations are deemed to be within the scope and spirit of the present invention as defined by the accompanying Claims to Invention. 

What is claimed is:
 1. A method of managing the proactive spraying of environmentally-clean anti-fire (AF) chemical liquid on GPS-specified property surfaces so as to inhibit fire ignition and flame spread in the presence of wild fire, said method comprising: (a) deploying a wireless system network supporting a command center, a network database, a plurality of mobile anti-fire chemical liquid spraying systems, and a plurality of mobile computing systems, each being operably connected to a wireless communication network; (b) in said network database, registering the GPS address of one or more GPS-specified parcels of property in a specified region, which may or may not have buildings constructed thereon; (c) deploying at least one of said mobile anti-fire chemical liquid spraying systems to a GPS-specified location, for spraying the GPS-specified parcels of property with an environmentally-clean anti-fire chemical liquid; (d) deploying a supply of said environmentally-clean anti-fire chemical liquid to the GPS-specified location of each said mobile anti-fire chemical liquid spraying system, and filling said mobile anti-fire chemical liquid spraying system with said supply of environmentally-clean anti-fire chemical liquid; (e) using said deployed mobile anti-fire chemical liquid spraying system to apply said environmentally-clean anti-fire chemical liquid spray to said GPS-specified parcel of property, while remotely monitoring the application of the environmentally-clean anti-fire chemical liquid sprayed on said GPS-specified parcel of property on a given date, and automatically recording the GPS-tracked spraying operations in said network database; and (f) updating data records in said network database associated with each application of environmentally-clean anti-fire chemical liquid spray on one or more said GPS-specified parcels of property.
 2. The method of claim 1, wherein after step (d) and before step (e), the method further comprises: (i) collecting intelligence data, including historical data, pertaining to risks of fire ignition by wild fires in surrounding regions, and storing said intelligence data in said network database; (ii) based on said intelligence data, said command center generating a GPS-specified anti-fire spray protection map and task report for execution; and (iii) prior to the arrival of a wild fire to the specified region, said command center transmitting a request to said GPS-specified location, to apply said environmentally-clean anti-fire chemical liquid spray to said GPS-specified parcel of property, using said deployed mobile anti-fire chemical liquid spraying system.
 3. The method of claim 2, wherein step (i) comprises using remote imaging systems including multi-spectral imaging (MSI) systems and/or hyper-spectral-imaging (HSI) systems, for remotely sensing and gathering data about wild fires and wild fire progress in GPS-specified regions.
 4. The method of claim 2, wherein step (i) comprises using space/satellite-based and/or drone-based airborne vehicles remotely-controlled by a human operator, or guided under an automated navigation system.
 5. The method of claim 2, wherein step (i) comprises using remote sensing technologies including a Moderate Resolution Imaging Spectro-radiometer (MODIS) satellite system for generating MODIS imagery subsets from MODIS direct readout data acquired to produce satellite wild fire detection data maps.
 6. The method of claim 2, wherein step (i) further comprises, during each wild fire data sensing and mapping mission, capturing a series of multi-spectral imaging (MSI) images and hyper-spectral-imaging (HSI) images of said specified region during a wild fire, and mapping said captured images to GPS-specific coordinates, and transmitting said mapped data to said network database for storage, analysis and generation of GPS-specified flight plans, for supporting anti-fire (AF) chemical liquid spray operations designed to stall and suppress said wild fires, and mitigate risk of damage to property and harm to human and animal life.
 7. The method of claim 1, wherein step (d) comprises deploying said environmentally-clean anti-fire chemical liquid spray having a clinging agent which, when dried on the sprayed surface of property, enables its chemical molecules to cling to the surface of combustible materials, including vegetation, so that said chemical molecules interferes with the combustion phase of an incident wild fire.
 8. The method of claim 2, wherein step (i) comprises using deployed remote imaging systems enabling said command center to collect intelligence data about wild fire ignition risks and generate reports for transmission to said mobile computing systems used by home owners, contractors and administrators.
 9. The method of claim 1, wherein step (d) comprises using remote data sensing and capture instruments for (i) determining GPS-specified navigation plans for mobile anti-fire chemical liquid spraying systems, and (ii) practicing GPS-guided methods of wild fire defense. 